fluidics

简明释义

英[fluːˈɪdɪks]美[ˈflʊɪdɪks]

n. 应用流体学

英英释义

单词用法

同义词

反义词

例句

1.The area within the field of fluidics in which components and systems perform functions such as sensing, logic, amplification, and control without the use of mechanical parts.

射流技术的一个领域，其部件和系统执行诸如传感、逻辑、放大和控制之类的功能，而不使用机械零件。

2.The area within the field of fluidics in which components and systems perform functions such as sensing, logic, amplification, and control without the use of mechanical parts.

射流技术的一个领域，其部件和系统执行诸如传感、逻辑、放大和控制之类的功能，而不使用机械零件。

3.In this Paper, a new tyPe of hyperbolic coal furnace of Pearlite expansion is discussed according to the principle of fluidics. Living examples are used for verification.

本文运用流体射流原理，对新型双曲线煤烧珍珠岩膨胀炉进行了分析探讨，并从实例进行了分析验证。

4.This paper, based on the theory of jet fluidics, had quested for the feasibility of utilizing the fire pool for cold storage air conditioning system.

本文从射流理论出发，探索利用消防水池进行蓄冷空调的可能性问题。

5.In this paper a fluidics device of continuous-path numerical control system for electrical spark machine tool is presented.

文章介绍了用于电火花线切割机床连续轨迹式数字程序控制的射流装置。

6.Digital fluidics is the latest thing in "lab on a chip" technology.

数字流体是“片上实验室”技术的最新产物。

7.The new research in fluidics 流体学 has opened up possibilities for more efficient microfluidic devices.

新研究中的流体学 fluidics 为更高效的微流体设备开辟了可能性。

8.In biomedical applications, fluidics 流体学 is crucial for developing lab-on-a-chip technologies.

在生物医学应用中，流体学 fluidics 对于开发实验室芯片技术至关重要。

9.The principles of fluidics 流体学 are used to design better drug delivery systems.

利用流体学 fluidics 的原理可以设计出更好的药物输送系统。

10.Researchers are exploring how fluidics 流体学 can improve environmental monitoring systems.

研究人员正在探索流体学 fluidics 如何改善环境监测系统。

11.Innovations in fluidics 流体学 have led to advancements in chemical analysis techniques.

在流体学 fluidics 方面的创新推动了化学分析技术的发展。

作文

In the realm of engineering and technology, the term fluidics (流体学) has emerged as a significant field that focuses on the behavior of fluids in various systems. This area of study is not only crucial for understanding natural phenomena but also for developing innovative technologies that can enhance our daily lives. Fluidics encompasses the principles of fluid dynamics and applies them to create devices that manipulate and control fluid flow. From medical devices to industrial applications, the implications of fluidics are vast and varied. One of the most fascinating aspects of fluidics is its application in microfluidic devices. These tiny systems can handle minute volumes of fluids, often at the scale of microliters or even nanoliters. Microfluidics has revolutionized fields such as biotechnology and chemistry by allowing for rapid analysis and experimentation with minimal sample sizes. For instance, in medical diagnostics, fluidics technology enables the development of portable devices that can perform complex tests quickly and accurately, providing results that were previously only possible in large laboratory settings. Moreover, the principles of fluidics are not limited to liquids alone; they also extend to gases. This versatility allows engineers to design systems that can optimize the flow of both types of fluids, leading to more efficient processes in industries ranging from aerospace to environmental engineering. The ability to control fluid behavior precisely can lead to significant improvements in energy efficiency and resource management, which are critical in today’s world where sustainability is a key concern. The design of fluidics systems often involves intricate channel networks and components that can guide and manipulate the flow of fluids in desired ways. For example, in lab-on-a-chip technologies, small channels are created on a single chip to facilitate chemical reactions and analyses. This integration of multiple functions into a compact device exemplifies how fluidics can streamline processes and reduce costs in research and industry. Furthermore, the study of fluidics has led to advancements in the field of robotics. Soft robotics, which utilize flexible materials and fluid-driven actuators, have shown great promise in applications ranging from medical devices to exploration in hazardous environments. By mimicking the movement of biological organisms, these robots can navigate complex terrains and perform tasks that traditional rigid robots may struggle with. The incorporation of fluidics in robotics not only enhances functionality but also opens up new possibilities for innovation in automation and artificial intelligence. In conclusion, fluidics (流体学) is a dynamic and interdisciplinary field that plays a pivotal role in modern technology and engineering. Its applications range from healthcare to environmental solutions, showcasing its importance in addressing contemporary challenges. As research continues to advance, the potential for fluidics to contribute to groundbreaking innovations remains immense. Understanding and mastering the principles of fluidics will undoubtedly be essential for future engineers and scientists as they strive to create more efficient, sustainable, and effective systems in an ever-evolving world.